KR101170739B1 - Geothermal exchanger assembly and method for installing the same into ground - Google Patents

Abstract

A novel underground geothermal heat exchanger assembly and a method for direct construction using the geothermal heat exchanger assembly are disclosed. The geothermal heat exchanger assembly is generally U-shaped, the geothermal heat exchange pipe to be filled with the heat exchange medium is embedded in the longitudinal direction and the filler is filled in the periphery of the geothermal heat exchange pipe, one side has a protruding shape and the other side is threaded in the circumferential direction The formed ground heat exchanger base member; The geothermal heat exchange pipe is embedded in the longitudinal direction so as to correspond to the geothermal heat exchange pipe in parallel with the geothermal heat exchanger base member side, and the filler is filled in the periphery of the geothermal heat exchange pipe, and the screw is formed on a part of the other side of the geothermal heat exchanger base member. A ground heat exchanger intermediate heat member coupled thereto; And a geothermal heat exchange pipe embedded in the longitudinal direction so as to correspond to the geothermal heat exchange pipe in parallel with the geothermal heat exchanger side, and a filler is filled in the periphery of the geothermal heat exchange pipe and screwed to the geothermal heat exchanger intermediate heat member. And a heat exchanger closure member. According to such a ground heat exchanger assembly and its construction method, construction of the ground heat exchanger is quick and easy, which is very advantageous labor and economically. In other words, when installing a vertically sealed underground heat exchanger to use shallow geothermal energy, the geothermal heat exchange pipe and grouting are integrated and manufactured according to the geological conditions on the ground to reduce the construction stage, simplifying the construction method and at the same time. The cost savings can be reduced, and the quality of ground heat exchangers can be standardized and innovatively improved. On the other hand, it can improve the working environment in an environmentally friendly way and increase the safety of working people.

Description

Vertical sealed underground heat exchanger assembly and construction method {GEOTHERMAL EXCHANGER ASSEMBLY AND METHOD FOR INSTALLING THE SAME INTO GROUND}

The present invention relates to a direct construction using a geothermal heat exchanger assembly and a geothermal heat exchanger assembly.

Geothermal energy generally refers to a characteristic of maintaining a constant temperature throughout the year at a certain depth. Therefore, it can be classified into shallow geothermal and deep geothermal according to the depth from the ground surface, and can be classified into direct use and indirect use technology in terms of use. Direct use supplies energy from 10-20 ℃ underground to the heat source of energy converters such as heat pumps or freezers to heat and cool buildings, snow melting, hot springs, aquaculture and farming facilities. It is used for district heating. Indirect utilization technology is geothermal power generation technology that draws hot water or steam above about 120 ℃ of deep geothermal heat to the ground and uses it to generate electricity by turning turbines. Geothermal energy varies widely depending on the region and geological conditions and therefore varies widely over the range of temperatures available. Currently in Korea, geothermal technology is mostly geothermal heat pump systems that heat or heat buildings or supply hot water. Finishing is done by inserting a male tube used as a ground heat exchanger pipe into the borehole and then refilling the half space between the pipe and the borehole with grouting materials. Geothermal heat exchanger pipes are currently mainly used high density polyethylene (HDPE) or polybutylene (PB) pipe. The grouting material promotes heat transfer to the ground heat exchanger circulation fluid and soil or rocks around the drilling hole, blocks water from entering the drilling hole from the ground surface, and prevents groundwater from entering the drilling hole. Block the potential groundwater contamination. As the grouting material, bentonite-based or cement-based materials having low permeability are mainly used. The geothermal pipe selects suitable grouting materials by analyzing the geological conditions in the area where the system will be installed when designing the entire system for long-term operation. Because the grouting material is an important factor in the heat transfer between the geology (soil or rock) and the geothermal heat pipe, there are other important factors such as the surface area (heat transfer area) and the geothermal thermal properties of the geothermal heat pipe. The geothermal material properties are influenced by various factors such as seasonality, annual rainfall and changes in water content of the soil or rock around the underground heat exchanger according to system operation. The initial cost of geothermal heat pump system is composed of heat pump purchase cost, underground heat pipe construction cost (drilling hole drilling, grouting material purchase, geothermal heat pipe purchase), indoor air conditioning equipment purchase cost and installation cost, and automatic control device installation cost. Heat pipe construction costs account for about 40-50% of the total. Therefore, the underground drilling process, geological condition analysis, geothermal pipe insertion, grouting material injection process, etc. occupy a relatively large time and cost, and are important factors influencing the success of the geothermal system.

The present invention has been made to solve the problems of the prior art, an object of the present invention is to provide an underground heat exchanger assembly and its construction method that allows the underground heat exchanger to be buried immediately underground after drilling a borehole. It's there.

Another object of the present invention is to provide a geothermal heat exchanger assembly and a construction method thereof, which can achieve a tight coupling between geothermal heat exchange pipes when assembling the geothermal heat exchanger assembly.

In order to achieve the above and other objects, one aspect of the present invention,

The geothermal heat exchange pipe which is generally U-shaped and contains heat exchange medium is embedded in the longitudinal direction, and the filler is filled in the periphery of the geothermal heat exchange pipe. absence;

The geothermal heat exchange pipe is embedded in the longitudinal direction so as to correspond to the geothermal heat exchange pipe in parallel with the geothermal heat exchanger base member side, and the filler is filled in the periphery of the geothermal heat exchange pipe, and the screw is formed on a part of the other side of the geothermal heat exchanger base member. A ground heat exchanger intermediate heat member coupled thereto; And

Geothermal heat exchanger is embedded in the longitudinal direction to correspond to the geothermal heat exchanger pipe side-by-side heat exchanger pipe in the longitudinal direction, and the filling material is filled around the geothermal heat exchanger pipe, the geothermal heat screwed to the geothermal heat exchanger intermediate heat member A ground heat exchanger assembly is provided that includes an exchanger closure member.

In the present invention, a part or all of the outer circumferential surface of the underground heat exchanger assembly is characterized by a thread shape.

In the present invention, the geothermal heat exchange pipe is provided at the connection site between the ground heat exchanger base member and the geothermal heat exchanger intermediate heat member and the connection site between the geothermal heat exchanger intermediate heat member and the geothermal heat exchanger closing member, respectively. A portion of either or both of them has a stretchable geothermal exchange pipe portion that is provided to be stretchable in the longitudinal direction.

As a preferred embodiment thereof, a part or all of the outer side of the stretchable geothermal heat exchange pipe portion oriented side by side in the longitudinal direction has a thread structure, and gears operating in engagement with the outer thread structure of the stretchable geothermal heat exchange pipe portion are respectively disposed. And the gears are arranged to rotate with each other.

In a more preferred embodiment thereof, the flexible geothermal heat exchange pipe portion is densely coupled by the expansion and contraction of the geothermal heat exchange pipe portion and the flexible geothermal heat exchange pipe portion corresponding thereto, and the inner circumferential surface of the flexible geothermal heat exchange pipe portion and male and female The inner circumferential surface of the geothermal heat exchange pipes to be coupled is configured to be arranged side by side.

At this time, any one or both of the gear is characterized in that it is configured to be operated by the external force operating member coupled to the shaft.

The filler is characterized in that at least one selected from cement, bentonite, sand, and a mixture of soybean and sand.

Another aspect of the present invention,

(a) obtaining and analyzing geological information of the region to be buried underground heat exchanger;

(b) the ground heat exchanger base member, the ground heat exchanger intermediate heat member and the ground of the above-described ground heat exchanger assembly having a filler material corresponding to the lipid of the geothermal heat exchanger embedding area based on the data analyzed through step (a). Prefabricating the heat exchanger closure member on the ground;

(c) drilling a vertical hole smaller than the diameter of the thread formed on the outer circumferential surface of the ground heat exchanger assembly manufactured according to step (b) and equal to or larger than the diameter of the outer circumferential surface of the ground heat exchanger assembly;

(d) inserting the underground heat exchanger base member manufactured through step (b) into the vertical hole while rotating through the vertical hole formed through step (c);

(e) screwing the geothermal heat exchanger intermediate heat member to one end of the geothermal heat exchanger base member, and then rotating the geothermal heat exchanger base member and the geothermal heat exchanger intermediate heat member together while rotating the geothermal heat exchanger intermediate heat member. Injecting until the top reaches the ground surface;

(f) screwing the geothermal heat exchanger closing member to one end of the geothermal heat exchanger intermediate heat member, and then rotating the geothermal heat exchanger base member, the geothermal heat exchanger intermediate heat member and the geothermal heat exchanger closing member together. Injecting together the ground heat exchanger closing member until the top reaches the ground surface; And

If necessary, (g) filling the gap between the underground heat exchanger assembly fully fastened and inserted through the steps up to (f) and the vertical hole drilled by step (c) by vibration. It provides a ground heat exchanger construction method.

Preferably, in the above steps (e) and (f), any one of the gears which rotates in engagement with the outer surface of the stretchable geothermal heat exchange pipe portion is forcibly rotated so that the stretchable geothermal heat exchange pipe portion is tightly inserted into the target geothermal heat exchange pipe portion. It further comprises a step of combining.

According to the ground heat exchanger assembly and the construction method thereof according to the present invention, not only the construction of the ground heat exchanger is simple, but also the dense coupling between the ground heat exchange pipes is possible.

1 is an exploded perspective view of an underground heat exchanger assembly according to a preferred embodiment of the present invention.
FIG. 2 is a cross-sectional view of the underground heat exchanger foundation member located at the bottom of the ground heat exchanger assembly shown in FIG. 1.
3 is a cross-sectional view of the geothermal heat exchanger intermediate heat member located in the intermediate heat of the geothermal heat exchanger assembly shown in FIG.
FIG. 4 is a cross-sectional view of the ground heat exchanger closing member positioned at the top of the ground heat exchanger assembly shown in FIG. 1.
5 is a cross-sectional view after coupling of the underground heat exchanger assembly shown in FIG. 1.
6 is a schematic cross-sectional view showing a bore hole drilled for embedding an underground heat exchanger assembly in the ground according to the present invention.
FIG. 7 is a view schematically illustrating a process of fitting the underground heat exchanger base member located at the lowermost of the underground heat exchanger assembly according to the present invention to the borehole shown in FIG. 6.
8 is a view illustrating a process of embedding in a bore hole while rotating the ground heat exchanger base member after the process of FIG. 7.
FIG. 9 is a diagram illustrating a process of joining a geothermal heat exchanger intermediate heat member to a geothermal heat exchanger base member after the process of FIG. 8 and then embedding it in a borehole while rotating together.
FIG. 10 is a view illustrating a process in which the ground heat exchanger closing member is coupled to the ground heat exchanger intermediate heat member after the process of FIG. 9 and then embedded in the borehole while rotating together.
11 to 13 show another series of examples of geothermal heat exchange pipes embedded in a geothermal heat exchanger assembly, which sequentially shows the tight coupling process of geothermal heat exchange pipes.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in more detail with reference to the following illustrative drawings.

Referring to FIG. 1, a ground heat exchanger assembly according to one preferred embodiment of the present invention includes a ground heat exchanger foundation member (10) embedded at the bottom of a borehole, and one or more ground heat exchanger intermediate rows disposed therein and inserted therein. And a ground heat exchanger closing member 30 disposed above and inserted into the ground heat exchanger intermediate heat member 20.

Referring to FIG. 2 together with FIG. 1, geothermal heat exchange pipes 12a and 12b are embedded in the ground heat exchanger base member 10 in the longitudinal direction. The geothermal heat exchange pipes 12a and 12b are generally U-shaped, one serving as an inlet port and the other serving as an outlet port. The geothermal heat exchange pipes 12a and 12b contain heat exchange media after construction is completed. The filler is filled around the geothermal heat exchange pipes 12a and 12b. Filler is optionally filled according to the geological conditions of the site where it is constructed. Representative non-limiting examples of fillers may include cement, bentonite, sand, and mixtures of soybean and sand. The upper portion of the underground heat exchanger base member 10 in construction is formed with threads for engagement as shown. On the other hand, a thread is formed on the outer circumferential surface of the ground heat exchanger base member 10 so as to be easily inserted into the bore hole by the rotation thereof.

Referring to FIG. 3 along with FIG. 1, each of the geothermal heat exchanger intermediate heat members 20 has geothermal heat exchange pipes 22a and 22b corresponding to the geothermal heat exchange pipes 12a and 12b side by side. Is embedded in the longitudinal direction. The geothermal heat exchange pipes 22a and 22b likewise serve as inlet ports and the other as outlet ports. The geothermal heat exchange pipes 22a and 22b contain heat exchange media after construction is completed. The filling material is selectively filled around the geothermal heat exchange pipes 22a and 22b according to the construction site. Non-limiting examples of such fillers may include cement, bentonite, sand, and mixtures of soybean and sand. In the construction, the lower portion and the upper portion of the underground heat exchanger base member 10 are formed with threads for coupling. On the other hand, on the outer circumferential surface of the intermediate heat exchanger intermediate heat member 20, a thread is easily formed into the bore hole by the rotation thereof.

Referring to FIG. 1 along with FIG. 4, the ground heat exchanger closing member 30 has a length of the ground heat exchanger pipes 32a and 32b in parallel with the ground heat exchanger pipes 22a and 22b. Buried in the direction. The geothermal heat exchange pipes 32a and 32b likewise serve as inlet ports and the other as outlet ports. The geothermal heat exchange pipes 32a and 32b contain heat exchange media after construction is completed. The filling material is selectively filled around the geothermal heat exchange pipes 32a and 32b according to the construction site. Non-limiting examples of such fillers may include cement, bentonite, sand, and mixtures of soybean and sand. The construction lower portion of the ground heat exchanger closing member 30 is formed as shown for the thread for coupling. On the other hand, on the outer circumferential surface of the ground heat exchanger closing member 30, a thread is easily formed in the bore hole by the rotation thereof.

The geothermal heat exchanger foundation member 10, the geothermal heat exchanger intermediate heat member 20 and the geothermal heat exchanger closing member 30 are finally screwed together to form an assembly as shown in FIG.

6 to 10 sequentially illustrate the construction method of the underground heat exchanger assembly according to the present invention. In the following, a construction method of a ground heat exchanger assembly according to the present invention will be described with reference to these drawings.

First, after obtaining and analyzing the geological information of the geothermal heat exchanger embedding target area, the individual members of the geothermal heat exchanger assembly as described above are first manufactured on the ground. Individual members of the geothermal heat exchanger assembly refer to the geothermal heat exchanger base member 10, the geothermal heat exchanger intermediate heat member 20, and the geothermal heat exchanger closure member 30 as described above. Those skilled in the art having the benefit of the present disclosure will be able to make individual geothermal heat exchanger individual members utilizing known techniques based on the disclosed subject matter described above.

Then, as shown in Figure 6 in the place (G) to install the underground heat exchanger drilling holes such as the vertical hole of the diameter d ₁ using equipment. At this time, the diameter (d ₁ ) of the vertical hole is equal to or does not exceed the diameter (d2) of the valley of the thread structure formed on the outer surface of the ground heat exchanger assembly.

Subsequently, the underground heat exchanger base member 10 of the underground heat exchanger assembly manufactured as described above is vertically inserted into the perforated vertical hole as shown in FIG. As shown in the drawing, the screw is rotated using the thread structure formed on the outer surface thereof and inserted into the vertical hole. Then, when the underground heat exchanger base member 10 is inserted into the vertical hole to some extent, the underground heat exchanger intermediate heat member 20 is screwed in as shown in FIG. ) And the underground heat exchanger intermediate heat member 20 are rotated together to be further inserted into the vertical hole. At this time, the inlet port and the outlet port of the geothermal heat exchange pipe formed in each member should be parallel to each other.

Subsequently, as shown in FIG. 10, the underground heat exchanger closing member 30 is screwed into the upper surface of the underground heat exchanger intermediate heat member 20, and then the underground heat exchanger base member 10 and the underground Rotation with the heat exchanger middle heat member 20 allows the top of the ground heat exchanger closing member 30 to be further inserted until it reaches the ground surface. The subsequent process is similar to the process after embedding a conventional underground heat exchanger, but the present invention does not require a separate filler in the space between the underground heat exchanger and the vertical hole. If necessary, the ground heat exchanger assembly may be intimately coupled with the ground, for example, by vibrating the ground heat exchanger assembly or the ground in which the ground heat exchanger assembly is embedded.

11 to 13 show even more preferred embodiments of the present invention.

In these figures, the ground heat exchanger base member 10 and the ground heat exchanger intermediate heat member 20 are coupled to each other, and the ground heat exchange pipes are respectively embedded in the ground heat exchanger base member 10 and the ground heat exchanger intermediate heat member 20. Is shown to be tightly coupled without leakage of the heat exchange medium. Although not shown in the figures, it should be understood that the combination of the geothermal heat exchanger intermediate heat member 20 and the geothermal heat exchanger closure member 30 also follows.

Referring to these figures, the connection site between the geothermal heat exchanger foundation member 10 and the geothermal heat exchanger intermediate heat member 20 (and between the geothermal heat exchanger intermediate heat member 20 and the geothermal heat exchanger closing member 30) is described. Part of the geothermal heat exchanger intermediate heat member side geothermal heat exchange pipes 22a, 22b in the geothermal heat exchange pipes 12a, 12b, 22a, 22b respectively provided at the connecting portion), i.e., the flexible geothermal heat exchange pipe portion 22a in the drawing. ', 22b') is configured to stretch in the longitudinal direction as shown. The outer circumferential surfaces of the flexible geothermal heat exchange pipe parts 22a 'and 22b' have a structure of a constant arrangement so as to be interlocked with the teeth of the gears, as shown in the enlarged part of FIG. 11, and the flexible geothermal heat exchange pipe parts 22a extending side by side. ', 22b') are arranged with two gears 26a and 26b to rotate in engagement with the outer circumferential surfaces of the flexible geothermal heat exchange pipe portions 22a 'and 22b'. The two gears 26a and 26b are also arranged to rotate in engagement with each other. On the other hand, the portions of the geothermal heat exchange pipes 12a and 12b on the ground heat exchanger base member side have an expanded inner diameter as shown. As a result, when any one of the gears 26a and 26b is operated, the stretchable geothermal heat exchange pipe portions 22a 'and 22b' are completely included. At this time, the inside of the flexible geothermal heat exchange pipe portion is preferably equal to the internal diameters of the geothermal heat exchange pipes 12a and 12b of the underground heat exchanger base member 10 placed at its lower end so as not to disturb the flow of the heat exchange medium. This process can be performed by interconnecting underground heat exchanger assemblies, such as the ground heat exchanger foundation member 10 and the ground heat exchanger intermediate heat member 20 and / or the ground heat exchanger intermediate heat member 20 and the ground heat exchanger closure member 30. After external engagement between the two), it is carried out by forcibly rotating one of the above-described gear (26a, 26b). That is, after each underground heat exchanger assembly member as shown in FIG. 11 is threaded together with each other as shown in FIG. 12, the geothermal heat exchange pipes 12a and 12b (22a) as shown in FIG. 13 by operation of the gears 26a and 26b. , 22b) are tightly coupled to each other.

10: underground heat exchanger foundation member
12a, 12b, 22a, 22b, 32a, 32b: geothermal heat exchange pipe
22a ', 22b': part of flexible geothermal heat exchange pipe
20: underground heat exchanger intermediate heat member
26a, 26b: gears
30: ground heat exchanger closing member

Claims (10)

Geothermal heat exchange pipes (12a, 12b) are generally U-shaped, the heat exchange medium (12a, 12b) is embedded in the longitudinal direction and the filler is filled around the geothermal heat exchange pipes (12a, 12b), one side has a protruding shape and the other part Underground heat exchanger base member (10) having threads formed in the circumferential direction;
Geothermal heat exchange pipes (22a, 22b) are embedded in the longitudinal direction to correspond to the geothermal heat exchange pipes (12a, 12b) side by side of the ground heat exchanger base member and the filler is filled around the geothermal heat exchange pipes (22a, 22b) At least one underground heat exchanger intermediate heat member (20) screwed to a thread formed on a portion of the other side of the ground heat exchanger base member (10); And
The geothermal heat exchange pipes 32a and 32b are embedded in the longitudinal direction so as to correspond to the geothermal heat exchanger pipes 22a and 22b in parallel with the geothermal heat exchanger, and the filler is filled around the geothermal heat exchange pipes 32a and 32b. A ground heat exchanger closing member (30) screwed to the ground heat exchanger intermediate heat member (20);
At the connection site between the geothermal heat exchanger foundation member 10 and the geothermal heat exchanger intermediate heat member 20 and the connection site between the geothermal heat exchanger intermediate heat member 20 and the geothermal heat exchanger closing member 30. A part of any one or both of the geothermal heat exchange pipes 12a, 12b, 22a, 22b, 32a, 32b, which are provided respectively, is provided in a stretchable geothermal heat exchange pipe portion 22a ', 22b provided to be stretchable in the longitudinal direction. ') (32a', 32b '). The geothermal heat exchanger assembly of claim 1, wherein some or all of the outer circumferential surface of the geothermal heat exchanger assembly is threaded. delete 3. A portion or all of the outer side of the flexible geothermal heat exchange pipe portions 22a ', 22b' (32a ', 32b') oriented side by side in the longitudinal direction has a threaded structure, and the flexible geothermal heat exchange pipe Gears 26a and 26b, which operate in engagement with the outer threaded structures of the parts 22a 'and 22b', 32a 'and 32b', are arranged respectively, and the gears 26a and 26b can interlock and rotate. Ground heat exchanger assembly, characterized in that arranged to be. 5. The flexible geothermal heat exchange pipe portions (22a ', 22b') (32a ', 32b') corresponding to the geothermal heat exchange pipes and the flexible geothermal heat exchange pipe portions (22a ', 22b') 32a. ', 32b') is densely coupled to the inner circumferential surface of the stretchable geothermal exchange pipe portions 22a ', 22b', 32a 'and 32b' and the male and female geothermal exchange pipes 12a are 12b) is characterized in that the inner circumferential surface is arranged side by side. 5. The underground heat exchanger assembly (100) according to claim 4, wherein any one or both of the gears (26a) (26b) are configured to be operated by an external force actuating member coupled axially. 2. The underground heat exchanger assembly of claim 1, wherein said filler is selected from at least one of cement, bentonite, sand, and a mixture of soybean and sand. (a) obtaining and analyzing geological information of the region to be buried underground heat exchanger;
(b) a geothermal heat exchanger foundation member (10) of the geothermal heat exchanger assembly according to claim 2 or 5 having a filler material corresponding to the geology of the geothermal heat exchanger embedding area, based on the data analyzed through step (a). ), Manufacturing at least one geothermal heat exchanger intermediate heat member 20 and a geothermal heat exchanger closure member 30;
(c) drilling a vertical hole smaller than the diameter of the thread formed on the outer circumferential surface of the ground heat exchanger assembly manufactured according to step (b) and equal to or larger than the diameter of the outer circumferential surface of the ground heat exchanger assembly;
(d) inserting the underground heat exchanger base member (10) manufactured through the step (b) into the vertical hole formed through the step (c) while rotating it;
(e) screwing the geothermal heat exchanger intermediate heat member 20 to one end of the geothermal heat exchanger base member 10, and then the geothermal heat exchanger base member 10 and the geothermal heat exchanger intermediate heat member 20 Rotating) together until the top of the ground heat exchanger intermediate heat member 20 reaches the ground surface; And
(f) screwing the geothermal heat exchanger finishing member 30 to one end of the geothermal heat exchanger intermediate heat member 20, and then the geothermal heat exchanger base member 10 and the geothermal heat exchanger intermediate heat member 20 And rotating together the ground heat exchanger closing member (30) until the upper end of the ground heat exchanger closing member (30) reaches the ground surface. 9. The method of claim 8, wherein (g) the clearance between the underground heat exchanger assembly fully fastened and inserted through steps (a) through (f) and the vertical hole drilled by step (c) is subjected to vibration. Geothermal heat exchanger construction method further comprising the step of filling. (a) obtaining and analyzing geological information of the region to be buried underground heat exchanger;
(b) the geothermal heat exchanger foundation member 10 of the geothermal heat exchanger assembly according to claim 5 having a filler material corresponding to the geology of the geothermal heat exchange site, based on the data analyzed through step (a); Manufacturing at least one exchanger middle heat member 20 and a ground heat exchanger closing member 30, respectively;
(c) drilling a vertical hole smaller than the diameter of the thread formed on the outer circumferential surface of the ground heat exchanger assembly manufactured according to step (b) and equal to or larger than the diameter of the outer circumferential surface of the ground heat exchanger assembly;
(d) inserting the underground heat exchanger base member (10) manufactured through the step (b) into the vertical hole formed through the step (c) while rotating it;
(e) screwing the geothermal heat exchanger intermediate heat member 20 to one end of the geothermal heat exchanger base member 10, and then the geothermal heat exchanger base member 10 and the geothermal heat exchanger intermediate heat member 20 Rotating) together until the top of the ground heat exchanger intermediate heat member 20 reaches the ground surface; And
(f) screwing the geothermal heat exchanger finishing member 30 to one end of the geothermal heat exchanger intermediate heat member 20, and then the geothermal heat exchanger base member 10 and the geothermal heat exchanger intermediate heat member 20 And rotating together the ground heat exchanger closing member 30 until the top of the ground heat exchanger closing member 30 reaches the ground surface.
Force rotation of one of the gears 26a and 26b which rotates in engagement with the outer surfaces of the flexible geothermal heat exchange pipe portions 22a ', 22b', 32a 'and 32b' in the above steps (e) and (f). Further comprising the step of tightly coupling the flexible geothermal heat exchange pipe portions (22a ', 22b') (32a ', 32b') to the geothermal heat exchange pipe portions to be inserted.

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